Feeding system

ABSTRACT

A method of producing copies on nonfibrous, flexible transfer sheets in electrophotographic copying apparatus. In order to reduce friction between each of the nonfibrous transfer sheets in the supply stack a sheet of paper is inserted between each nonfibrous sheet. The sheet-advancing member engages only the nonfibrous sheets and advances them seriatim into the copying apparatus, leaving the sheets of paper in the stack.

United States Patent 3,589,809 [72] Inventors Thomas B. Barker [56] References Cited Webster: 7 UNITED STATES PATENTS f fif'ggzgsf z' n s zf" 2,052,255 8/1936 Shoults 226/45 x 2] A l N 2,147,467 2/1939 Stephenson 226/45 x I 1 3,062,095 1 1/1962 Rutrus 355/3 x [22] Filed May 22, 1969 [45] Patented June 29, l97l OTHER REFERENCES [73] Assignee Xerox Corporation lBM TECHNICAL DISCLOSURE BULLETIN, Vol. 5 No.

Rochester, N.Y. 9, Feb. l963, copy in 226/45 Division ofser' June 1969 Primary ExaminerSamuel S. Matthews 35.11124 Assistant Examiner-Monroe H. Hayes Atlorneys Frank A. Steinhilper, Stanley 2. Cole and James J.

Ralabate a R ABSTRACT: A method of producing copies on nonfibrous, [54] flexible transfer sheets in electrophotographic copying aprawmg paratus. In order to reduce friction between each of the non- [52] [1.8. CI 355/17, fibrous transfer sheets in the supply stack a sheet of paper is 355/3 inserted between each nonfibrous sheet. The sheet-advancing [51] lnt.Cl ..G03g 13/00 member engages only the nonfibrous sheets and advances [50] Field of Search 355/3, l7; them seriatim into the copying apparatus, leaving the sheets of paper in the stack.

PATENTED M29 19?:

INVUNTORS CASIMIR -J. MYTYCH BRUCE D. MAC LELLAN THOMAS B. BARKER ATTORNEY FEEDING SYSTEM This is a division of application Ser. No. 598,279, filed in the U.S., Dec. 1, 1966 now US. Pat. No. 3,519,124.

This invention relates to articles and methods to feed nonfibrous, flexible sheets.

Ever since the early 1800s with the advent of the rotating cylinder printing press which greatly increased the number of impressions per hour over prior art sheet feed-imaging systems, those skilled in the art have been concerned with advancing the art of sheet feeding in order to keep up with sheetfed automated presses which can presently produce from 2,500 to 5,000 impressions per hour. In addition, in the last decade, there has been a revolution in office copying with the advent of new imaging processes and automatic imaging machines many of which call for automated sheet feeding. For example, see The Revolution ln Office Copying, Chemical and Engineering News, 1 l4, July 13, 1964.

Although paper is commonly used as an image-receiving member, certain nonfibrous, flexible sheet materials which may be relatively plastic, polymeric materials generally characterized by having a high surface gloss and a smooth surface are being increasingly employed as an image-receiving member for certain imaging applications. These nonfibrous, flexible sheet image-receiving members are often more durable than paper and transparent nonfibrous, flexible sheets after receiving the image have great utility for example as transparencies used in conventional projectors to project images on a screen, for example, for group presentation. However, a problem has arisen in that many currently available imaging machines are peculiarly adapted to feed seriatim stacked paper and certain operational difficulties have arisen when nonfibrous, flexible image-receiving sheets are substituted for paper in such systems.

For example in feeding seriatim nonfibrous, flexible sheets from the top of a stack of said sheets into an automatic imaging machine it is found that feeding of the top sheet often causes creep or advancement of the sheets immediately beneath the top sheet resulting in misfeeds and jams within the machine thus greatly increasing the amount of imaging material wasted which increases the cost of operation. Also machine downtime, necessary to clear the machine of jams, is increased. It is thought that creep is at least partially caused by the relatively high coefficient of sliding friction of many nonfibrous, flexible materials relative to'each other and also by the electrically insulating nature of many nonfibrous, flexible materials which permits electrostatic charges to accumulate on said sheets and electrostatically attract contiguous sheets when a sheet is removed from a stack of said sheets.

The building up of electrostatic charges on nonfibrous, flexible sheets also makes removal of the leading edge of sucha sheet from a flat surface, for example to change the routing of the sheet in processing, more difficult since the charged sheet adheres more tenaciously to the surface than would paper or a relatively uncharged sheet. These problems in a business where cost, ease and efficiency of operation are of utmost significance could not long be endured in any commercially offered imaging machine.

Another problem has been that feeding and processing of nonfibrous, flexible sheets along through some copiers employing heat fusing to pcrmanentize the image on the sheet is found to cause distortion and buckling of the sheet with resultant charring of portions of the sheet.

Also, as illustrated by copending application Ser. No:

procedures. It is found that a misrouted transparent or translucent nonfrbrous, flexible image-receiving sheet will often not activatesuch a device.

Thus there is a continuing need for smoother, more troublefree feeding and processing of nonfibrous, flexible imagereceiving sheets particularly into 'those imaging machines adapted to process more conventional-type image transfer material, such as paper.

It is therefore an object of this invention to provide articles and methods to feed seriatim nonfibrous, flexible sheets which overcome the above-noted disadvantages and satisfy the above-noted wants.

It is another object of this invention to provide an automatic feed system especially suited for feeding seriatim nonfibrous, flexible sheets from the top of a stack or supply thereof.

lt is a further object of this invention to provide a nonfibrous, flexible sheet feed system adapted to feed the topmost or bottommost nonfibrous, flexible sheet from a stack of said sheets without causing appreciable creep or advance of contiguous sheets in order to provide more trouble-free feeding and image processing.

It is a still further object of this invention to provide a nonf brous, flexible sheet feed and processing system capable of activating a photocell detection device within an imaging machine to detect misrouting of sheets within the'machine.

It is a still further object of this invention to provide an embodiment of a nonfibrous, flexible sheet feed system, wherein transfer images are more readily fused especially by heat radiation fusing techniques.

The foregoing objects and others are accomplished in accordance with this invention by providing according to a first article embodiment, an image transfer member comprising a nonfibrous, flexible image-receiving sheet backed by a sheet of paper substantially coextensive with the area of the nonfibrous, flexible sheet, the sheet of backing paper attached only to at least one of a common leading or side edge of the nonfibrous, flexible sheet.

As used in the specification and claims herein the directional describers, leading, side and back edges are intended to refer to sheet edge positions with respect to the direction of advancement of generally rectangular sheets for example in a sheet-feeding operation. Thus the leading edge is the edge which first advances into the machine and is generally perpendicular to the direction of advancement. The side edges are generally parallel to the direction of advancement, and so on. Each transfer member according to this first embodiment is automatically fed from a stack of members and processed as a unit i.e. with paper backing attached to only at least one common leading or side edge throughout the image- .processing operation, the paper backing to be removed or not as desired after the nonfibrous, flexible sheet has received the image and the unit has been discharged from the machine.

According to a second article embodiment of the invention, a stack of nonfibrous, flexible image-receiving sheets is interleafed by a stack of paper sheets bound only along at least one common side or back edge each nonfibrous, flexible sheet being separated from immediately adjacent sheets of similar material by at least one interleafed sheet of paper. The area of the paper sheets is substantially coextensive with the area of the nonfibrous, flexible sheets except for cutout portions of each paper sheet corresponding to the point of contact of nonfibrous, flexible sheet-separating and advancing rollers or other sheet-separating and advancing means of a sheet feed mechanism. The cutout portions permit the sheet-separating and advancing rollers or other sheet-separating and advancing means to contact and advance each successive nonfibrous, flexible image-receiving sheet into the machine to be processed by the machine absent the paper interleafing which is left behind as a stack of bound paper. The paper interleafs minimize the contact area between immediately adjacent nonfibrous, flexible sheets thus greatly reducing the creep of said sheets when immediately adjacent nonfibrous, flexible sheets are advanced into the machine.

an article for feeding seriatim stacked nonfibrous, flexible sheets according to a second embodiment of the invention;

F 16. 3 is a partially schematic side view of an exemplary au tomatic xerographic copying apparatus for utilizing either embodiment of the multifeed articles of this invention.

Referring now to FIG. 1 there is illustrated according to a first article embodiment of the invention, a novel image transfer member comprising nonfibrous, flexible sheet 12 Q the free surface of which is to bear the image and paper backing sheet 14 attached to a common peripheral leading or side edge of sheet 12 by an adhesive material 16. Of course a wide variety of means are available to secure common edges such as stapling, taping, gluing and other means known in the art. Optionally, and preferably sheet 12 may be creased or scored, the crease 18 positioned to facilitate the tearing away of the imaged portion of sheet 12 from the adhesively secured portion of the sheet to give an imaged nonfibrous, flexible sheet absent the paper backing'14.

Although it is found to be preferred to secure the imagereceiving sheet 12 to the paper backing 14 along the common leading edge, it is found that securing sheet 12 to backing sheet 14 along either side edge alone or in combination with securing of the lead edge is also suitable for use in the various machines tested. Perforation or crease 18 is preferred but is not a requirement of the invention since after imaging the transfer sheet 12 may be separated from the backing by a wide variety of ways for example by merely cutting as with a scissors to free the transfer sheet 12 from the backing l4 and any secured peripheral edge portions. Before separation the paper backing allows an imaged transparency to be more easily viewed and protects the adjacent surface of sheet 12 from dirt and other ambient influences which may tend to degrade the image projection qualities of sheet 12.

A multiplicity of members 10 may be stacked in the paper feed tray of many sheet-feed mechanisms for feeding a stack of ordinary paper sheets seriatim and each member may be fed as a unit smoothly while nonfibrous, flexible sheets 12 if stacked and fed without paper backing 14 attached as shown would not feed without frequent jams caused by creep of underlying sheets as topmost or bottommost sheets are fed off the stack. Member 10 is easily and cheaply manufactured and eliminates any special carriers and hand manipulations in multifeeding. In addition it has been found that especially in radiant heat systems of fusing or fixing the image to sheet 12 to render the imaged sheet indefinitely useable, the paper backing aids in converting radiant energy to heat the nonfibrous, flexible surface to fuse images including loose toner images deposited in the process of xerography when deposited on translucent or transparent nonfibrous, flexible sheets. Absent the backing much of the radiant energy might pass through the transparency with minimal heating of the nonfibrous, flexible material itself.

Referring now to FIG. 2 there is shown a second article embodiment for feeding seriatim image-receiving nonfibrous, flexible sheets from a supply thereof comprising a stack of said sheets 22, immediately adjacent sheets being interleafed with sheets of paper 20 bound along a common edge by binding 21 and having cutaway portions 23 to permit separating and advancing means for example rollers 41 in FIG. 3 to contact and advance seriatim nonfibrous image-receiving sheets 22 into the imaging machine. As will be understood by those skilled in the art binding 21 is illustrative and many others are available for use herein. The cutout areas 23 correspond to the contact positions of the separating and advancing means and therefore will vary depending upon the spacing used in the particular sheet feed device. It is found that by so interleafing nonfibrous image receiving sheets 22, the contact area between immediately adjacent nonfibrous sheets is minimized to make it possible to multifeed said sheets seriatim from the top or bottom of a stack with a minimum of creep of contiguous nonfibrous sheets. Of course in utilizing this embodiment of the invention in those machines with a photocell misrouting detector the leading edges of substantially nonreflective imagereceiving sheets 22 may readily be made light reflective by a wide variety of means for example by equipping the leading edge of each sheet with a strip of paper or other light-reflective material which may be detachable from the remaining portion of the image-receiving sheet after imaging if desired.

The paper interleafs 20 with binding 21 after feeding of the nonfibrous sheets may be discarded or utilized for example as a tablet of paper. The cutout portions 23 may be removed from each sheet by cutting or severing along a crease or perforation included as a part of each sheet.

Ordinarily it is advantageous to have as much paper interleaf as possible between adjacent nonfibrous sheets to reduce actual contact of said sheets to a minimum but it may be expedient for example to adapt the invention to a particular imaging machine to further cut away portions of each sheet of paper interleaf. For example it is found to be expedient to diagonally trim comers of paper interleafs along lines 25 to adapt the second embodiment of the invention for use with the separating and advancing means of the Xerox 813 office copier more fully described in Trumbull US. Pat. No. 3,148,601.

Nonfibrous, flexible sheets 12 and 22 illustrated in FIGS. 1 and 2 may be almost any film-formable, nonfibrous flexible material possessing sliding friction and electrostatic properties such that when multifed seriatim from the top or bottom of a stack of said sheets there is substantially less creep of underlying sheets as a result of a paper backing associated with the sheets as described herein and shown in FIGS. 1 and 2, to effect more troubleand jam-free operation of the particular imaging machine. The nonfibrous, flexible-imaging sheets for use herein should preferably be less than about 6 mils in thickness in order to permit feeding as a unit with paper backing 14, according to the first embodiment of the invention, through the sheet feed mechanism and the processing apparatus of a wide variety of imaging machines. According to the second embodiment because the sheet is fed and processed without any paper backing the nonfibrous sheets 22 may be up to about 10 or l2 mils in thickness and still be fed and processed by a wide variety of imaging machines.

Film-formable polymeric materials are perhaps the most prominent group of materials useful'as nonfibrous transfer sheets as described herein, which because of their sliding friction and electrostatic characteristics show markedly improved feeding characteristics when interleafed or backed with paper as described herein.

A preferred polymeric nonfibrous, flexible image transfer material for use in imaging machines has been found to be a polysulfone thermoplastic available in sheets of roughly 4 mils thickness under the trademark ROWLOX from Rowland Products, Inc., Kensingtom'Conn. This material in sheet form is very transparent and may be fed seriatim and processed satisfactorily to receive a high-quality image when'interleafed or backed with paper as described herein.

A second preferred polymeric nonfibrous material for use herein is polyethylene terephthalate polyester transparent sheet material available under the trademark MYLAR from the E. l. du Pont de Nemours & Co. and available in a wide range of thicknesses.

Many transparent as well as opaque polymeric materials are available in the art which may be formed into films to form image-receiving sheets for use herein. Any suitable filmformable polymeric material may be used. Typical transparent film formable polymeric materials include cellulose acetate, acrylics for example alphamethyl styrene copolymer, cellulose nitrate, epoxy resins, phenolics, phenol-formaldehyde, silicones, urethanes, ureaformaldehydes, polyesters for example polyethylene terephthalate, .polycarbonates, cellophane, polychlorotrifluoroethylene copolymers, polyvinyl-butyral, polymethyl methacrylate, polystyrenes, polyethylene and others. Typical film-formable polymeric materials which form films which are not necessarily clear or transparent include cellulose acetate (which may be clear, translucent or opaque), fluorohalocarbon, cellulose triacetate, cellulose acetate butyrate, polyurethane elastomer, cellulose proportionate, ethyl cellulose, polypropylene, polyvinyl fluoride, vinyl-chlorideacetate copolymers, vinylidene chloride-vinyl chloride copolymer, tetrafluoroethylene available under the trademark Teflon from E. l. du Pont de Nemours & Co., copolymers of hexafluoropropylene and polytetrafluoroethylene, polyvinyl chloride, polyacrylonitrile, cellulose nitrate plasticized with camphor, hard rubber such as ebonite and chlorinated rubber, nylons or polyamides, polyvinyl alcohol, polyvinylidinefluoride, copolymers of chlorotrifluoroethylene and vinylidine fluoride, casein, polyglycols, alkyds and others.

Paper sheets utilized herein are of substantially the same area as the nonfibrous, flexible image-receiving sheets and may comprise any conventional paper material.

Referring now to FIG. 3 there is illustrated partially schematically a xerographic-type-imaging machine of the type wherein the articles shown in FIGS. 1 and 2 have been shown to have great utility.

In the imaging process of xerography for example as disclosed in Carlson U.S. Pat. No. 2,297,691 a xerographic plate comprising a layer of photoconductive insulating material on a conductive backing is given a uniform electric charge over its surface and is then exposed to the subject matter to be reproduced, usually by conventional projection techniques. This exposure discharges the plate areas in accordance with the radiation intensity that reaches'them and thereby creates an electrostatic latent image on or in the photoconductive layer. Development of the latent image is effected with an electrostatically charged finely divided material such as an electroscopic powder that is brought into surface contact with the photoconductive layer and is held thereon electrostatically in a pattern corresponding to the electrostatic latent image. Thereafter, .the developed xerographic powder image is usually transferred to a support surface, for example paper, to which it may be affixed by any suitable means.

The xerographic apparatus illustrated shows a xerographic plate comprising a photoconductive insulating light-receiving layer on a conductive backing and formed in the shape of a drum 24 which is mounted on a shaft journaled in a frame of the machine to rotate in a counterclockwise direction to cause the drum surface sequentially to pass a plurality of xerographic-processing stations. At charging station 26 a uniform electrostatic charge is deposited on the photoconductive layer of the drum of for example by a corona discharge device as illustrated. Examples of typical corona discharge devices may be found in Vyverberg U.S. Pat. No. 2,836,725 and Walkup U.S. Pat. No. 2,777,957.

At exposure station 28 a light or radiation pattern for example of an image is projected onto the drum surface to dissipate the charged drum surface in light-struck areas and thereby form a latent electrostatic image of the copy to be reproduced.

At developing station 30 a xerographic developer material 32 comprising electroscopic marking particles called toner I of the type for example as described in lnsalaco U.S. Pat. Nos.

3,079,342, 2,891,011 or Carlson Re U.S. Pat. No. 25,136 is caused to be contacted with the latent electrostatic image on the drum surface whereby the toner particles adhere to the electrostatic latent image to form a loose xerographic powder image on the drum in the configuration of the copy to be reproduced.

At transfer station 34 the loose powder image is contacted and electrostatically transferred from the drum surface to an image transfer member for example a nonfibrous, flexible image-receiving sheet fed as described herein.

Thereafter the drum in its rotation passes drum-cleaning station 36 whereat the drum surface is brushed to remove residual toner particles remaining thereon after image transfer to ready the drum and the machine for another imagereproducing cycle.

At image transfer station 34 there is shown a sheet-feeding mechanism more particularly described in Eichler et al. U.S. Pat. No. 2,945,434 adapted to feed seriatim nonfibrous, flexible sheets according to this invention to the xerographic drum in coordination with the presentation of the developed image on the drum at the transfer station. This sheet-feeding mechanism generally designated 38 includes an image-receiving member source such as a tray 39 to hold a stack of members, a separating and advancing roller or rollers 41 adapted to feed seriatim the top sheet or member of the stack to feed rollers 43 by frictional contact of rollers 41 with the topmost sheet or member in the stack which directs the sheet material into contact with the rotating drum at a speed about equal to or slightly in excess of the rate of travel of the surface of the drum is coordination with the appearance of the developed image at the transfer station. To effect proper registration of the image-receiving member with the feed rollers 43 and to direct the sheet transfer material into contact with the drum, guides are positioned on opposite sides of the feed rollers.

It is understood that the invention hereof may be employed with a wide variety of sheet separating and advancing means other than rollers 41, such as vacuum gripper means for example as described in Williams U.S. Pat. No. 2,819,074 or Wagner U.S. Pat. No. 3,241,830, and other suitable sheetseparating and advancing means known in the art.

The transfer of the power image from the drum to the image-receiving member is aided by means of corona-charging device 40 which may be substantially similar to the device at charging station 26, which is located adjacent the point of contact between the image-receiving member and the rotating drum. The corona device creates an electrostatic field which is effective to attract the toner particles comprising the image from the drum and cause them to adhere electrostatically to the surface of the image-receiving member.

Immediately subsequent to the point of transfer is positioned an image-receiving member stripping apparatus or pickoff mechanism 42 for removing the image-receiving member from the drum surface. As illustrated the device includes a plurality of small-diameter multiple-outlet conduits of a manifold that is supplied with a pressurized gas for example air by a pulsator operated by a suitable power means. The pulsator is adapted to force jets of pressurized gas through the outlet conduits into contact with the surface of the drum slightly in advance of the image-receiving member to strip the leading edge of the member from the drum surface and to direct it onto an endless conveyor 44 whereby the member is carried to a fixing device for example heat fuser 46 whereby the developed and transferred xerographic powder image on the image-receiving member is permanently fixed thereto.

After fusing the finished copy is discharged by rollers 48 to copy holder 50.

Illustrated immediately subsequent to stripping apparatus 42 in the drum rotational sequence is photocell mispuff detector 52 which operates as previously described herein to receive sufiicient light reflected back to the photocell from the paper backing 14 of an image transfer member according to a first embodiment of this invention or the light-reflective surface of a nonfibrous member or a reflective leading edge of a translucent or transparent nonfibrous, flexible sheet according to a second embodiment of the invention to stop operation of the machine or to otherwise alert the operator to the mispuff.

The sheet feeding and imaging system illustrated in FIG. 3 is representative of the type employed in one of the most commercially successful imaging machines, the Xerox 914 office copier. According to a first embodiment of the invention, members comprising polysulfone sheets of about 4 mils in thickness available from Rowland Products, Inc. and backed by a thin onionskin paper of about 1.5 mils in thickness or a standard copypaper supplied for use in the 914 copier of about 3.0 to 3.5 mils in thickness were stacked according to both article embodiments thereof in tray 39 of the 914 copier and were fed satisfactorily with no adjusting of the machine from the-setting employed for paper transfer material.

It is to be noted that Rowland Products, Inc., expressly instructs that the polysulfone sheets it sells should be fed only asingle sheet at a time and as intimated from these instructions it is found that said sheets do not multifeed satisfactorily if fed from a stack of said sheets without employing the articles and methods of this invention.

Many other imaging machines employ sheet feed mechanisms for feeding sheets seriatim from a stack of sheets which makes them suited for employing the inventive embodiments disclosed herein. One such machine besides the Xerox 914 copier is the Xerox 813 copier wherein the thicker paper backings, greater than about 3 mils according to the first embodiment of the invention were found to be preferred with a combined nonfibrous sheet, paper backing thickness of not more than about 10 mils.

Any suitable imaging machine which employs a sheet feed mechanism for feeding sheets seriatim from a stack may utilize this invention to advantage to multifeed non fibrous, flexible sheets which do not feed satisfactorily without interleafing between adjacent nonfibrous sheets to decrease the coefficient of sliding friction and the electrostatic forces retarding advancement of sheets.

Although specific materials, dimensions and apparatus have been described in the above description of preferred embodiments of an article to feed seriatim nonfibrous, flexible sheets, other suitable materials and configurations as listed herein may be used with similar results. In addition other materials may be added to the nonfibrous, flexible materials or other materials listed herein or variations may be made in the various steps of sheet feeding or feeding apparatus described to enhance, or otherwise modify the invention. For example colorants may be added to nonfibrous, flexible sheets, for example films comprising polystyrenes to lend a colored hue to the imaged sheet.

It will be understood that various other changes in the details, materials, steps and arrangements of parts which have been herein described and illustrated in order to explain the nature of the invention will occur to and may be made by those skilled in the art upon a reading of this disclosure and such changes are intended to be included within the principle and scope of this invention.

What we claim is:

1. An electrophotographic process for the seriatim production of a plurality of marking material images on nonfibrous,

flexible transfer sheets comprising the steps of a. stacking a plurality of said transfer sheets in registration, b. interposing paper sheets between adjacent transfer sheets to reduce the frictional forces acting on the transfer sheets during their separation from said stack with the paper sheets being arranged in registration with each other and the transfer sheets,

forming an electrostatic latent image on a xerographic plate and developing the latent image with electroscopic marking material to form a marking material image,

. separating the outermost transfer sheet in the stack with sheet separating and advancing means brought into engagement with the outermost transfer sheet,

. enabling the sheet separating and advancing means to engage the next transfer sheet in the stack after separation of the outermost transfer sheet without interference from the paper sheet spacing the separated and adjacent transfer sheets,

f. advancing said separated transfer sheet into image-receiving relation with said xerographic plate and transferring said marking material image to said separated transfer sheet and repeating at least once steps (c) through (f) for seriatim production of the remainder of said plurality of marking material images on nonfibrous, flexible transfer sheets.

2. The process of claim 1 wherein said enabling step includes cutting out portions of said paper sheets to permit the sheet separating and advancing means to engage an adjacent transfer sheet through the cutout portion of a paper sheet.

3. The process of claim 1 wherein said enabling step includes coupling said paper sheets to said transfer sheets to separate a paper sheet from the stack with the outermost transfer sheet thereby removing paper sheets from between the outermost transfer sheet and the sheet separating and advancing means.

4. The process of claim 1 further including separating said outermost transfer sheet from an adjacent paper sheet in addition to separating the transfer sheet from the stack by binding a common edge of the paper sheets together whereby an adjacent paper sheet is restrained during the separation of a transfer sheet from the stack.

5. The process of claim 1 wherein said transfer sheets include a light-reflective strip detachably secured to said sheet so the strip can be removed after the production of a marking material image on the transfer sheet.

6. The process of claim 5 wherein said said strip is detachably secured to the leading edge of said transfer sheets.

7. The process of claim 5 further including the step of sensing light reflected from said strip to detect the presence of a transfer sheet. 

1. An electrophotographic process for the seriatim production of a plurality of marking material images on nonfibrous, flexible transfer sheets comprising the steps of a. stacking a plurality of said transfer sheets in registration, b. interposing paper sheets between adjacent transfer sheets to reduce the frictional forces acting on the transfer sheets during their separation from said stack with the paper sheets being arranged in registration with each other and the transfer sheets, c. forming an electrostatic latent image on a xerographic plate and developing the latent image with electroscopic marking material to form a marking material image, d. separating the outermost transfer sheet in the stack with sheet separating and advancing means brought into engagement with the outermost transfer sheet, e. enabling the sheet separating and advancing means to engage the next transfer sheet in the stack after separation of the outermost transfer sheet without interference from the paper sheet spacing the separated and adjacent transfer sheets, f. advancing said separated transfer sheet into image-receiving relation with said xerographic plate and transferring said marking material image to said separated transfer sheet and g. repeating at least once steps (c) through (f) for seriatim production of the remainder of said plurality of marking material images on nonfibrous, flexible transfer sheets.
 2. The process of claim 1 wherein said enabling step includes cutting out portions of said paper sheets to permit the sheet separating and advancing means to engage an adjacent transfer sheet through the cutout portion of a paper sheet.
 3. The process of claim 1 wherein said enabling step includes coupling said paper sheets to said transfer sheets to separate a paper sheet from the stack with the outermost transfer sheet thereby removing paper sheets from between the outermost transfer sheet and the sheet separating and advancing means.
 4. The process of claim 1 further including separating said outermost transfer sheet from an adjacent paper sheet in addition to separating the transfer sheet from the stack by binding a common edge of the paper sheets together whereby an adjacent paper sheet is restrained during the separation of a transfer sheet from the stack.
 5. The process of claim 1 wherein said transfer sheets include a light-reflective strip detachably secured to said sheet so the strip can be removed after the production of a marking mAterial image on the transfer sheet.
 6. The process of claim 5 wherein said said strip is detachably secured to the leading edge of said transfer sheets.
 7. The process of claim 5 further including the step of sensing light reflected from said strip to detect the presence of a transfer sheet. 